package z3 /* #include "z3.h" #include */ import "C" import ( "unsafe" ) // Floating-point operations // MkFPSort creates a floating-point sort. func (c *Context) MkFPSort(ebits, sbits uint) *Sort { return newSort(c, C.Z3_mk_fpa_sort(c.ptr, C.uint(ebits), C.uint(sbits))) } // MkFPSort16 creates a 16-bit floating-point sort. func (c *Context) MkFPSort16() *Sort { return newSort(c, C.Z3_mk_fpa_sort_16(c.ptr)) } // MkFPSort32 creates a 32-bit floating-point sort (single precision). func (c *Context) MkFPSort32() *Sort { return newSort(c, C.Z3_mk_fpa_sort_32(c.ptr)) } // MkFPSort64 creates a 64-bit floating-point sort (double precision). func (c *Context) MkFPSort64() *Sort { return newSort(c, C.Z3_mk_fpa_sort_64(c.ptr)) } // MkFPSort128 creates a 128-bit floating-point sort (quadruple precision). func (c *Context) MkFPSort128() *Sort { return newSort(c, C.Z3_mk_fpa_sort_128(c.ptr)) } // MkFPRoundingModeSort creates the rounding mode sort. func (c *Context) MkFPRoundingModeSort() *Sort { return newSort(c, C.Z3_mk_fpa_rounding_mode_sort(c.ptr)) } // MkFPNumeral creates a floating-point numeral from a string. func (c *Context) MkFPNumeral(value string, sort *Sort) *Expr { cStr := C.CString(value) defer C.free(unsafe.Pointer(cStr)) return newExpr(c, C.Z3_mk_numeral(c.ptr, cStr, sort.ptr)) } // MkFPInf creates a floating-point infinity. func (c *Context) MkFPInf(sort *Sort, negative bool) *Expr { return newExpr(c, C.Z3_mk_fpa_inf(c.ptr, sort.ptr, C.bool(negative))) } // MkFPNaN creates a floating-point NaN. func (c *Context) MkFPNaN(sort *Sort) *Expr { return newExpr(c, C.Z3_mk_fpa_nan(c.ptr, sort.ptr)) } // MkFPZero creates a floating-point zero. func (c *Context) MkFPZero(sort *Sort, negative bool) *Expr { return newExpr(c, C.Z3_mk_fpa_zero(c.ptr, sort.ptr, C.bool(negative))) } // MkFPAdd creates a floating-point addition. func (c *Context) MkFPAdd(rm, lhs, rhs *Expr) *Expr { return newExpr(c, C.Z3_mk_fpa_add(c.ptr, rm.ptr, lhs.ptr, rhs.ptr)) } // MkFPSub creates a floating-point subtraction. func (c *Context) MkFPSub(rm, lhs, rhs *Expr) *Expr { return newExpr(c, C.Z3_mk_fpa_sub(c.ptr, rm.ptr, lhs.ptr, rhs.ptr)) } // MkFPMul creates a floating-point multiplication. func (c *Context) MkFPMul(rm, lhs, rhs *Expr) *Expr { return newExpr(c, C.Z3_mk_fpa_mul(c.ptr, rm.ptr, lhs.ptr, rhs.ptr)) } // MkFPDiv creates a floating-point division. func (c *Context) MkFPDiv(rm, lhs, rhs *Expr) *Expr { return newExpr(c, C.Z3_mk_fpa_div(c.ptr, rm.ptr, lhs.ptr, rhs.ptr)) } // MkFPNeg creates a floating-point negation. func (c *Context) MkFPNeg(expr *Expr) *Expr { return newExpr(c, C.Z3_mk_fpa_neg(c.ptr, expr.ptr)) } // MkFPAbs creates a floating-point absolute value. func (c *Context) MkFPAbs(expr *Expr) *Expr { return newExpr(c, C.Z3_mk_fpa_abs(c.ptr, expr.ptr)) } // MkFPSqrt creates a floating-point square root. func (c *Context) MkFPSqrt(rm, expr *Expr) *Expr { return newExpr(c, C.Z3_mk_fpa_sqrt(c.ptr, rm.ptr, expr.ptr)) } // MkFPLT creates a floating-point less-than. func (c *Context) MkFPLT(lhs, rhs *Expr) *Expr { return newExpr(c, C.Z3_mk_fpa_lt(c.ptr, lhs.ptr, rhs.ptr)) } // MkFPGT creates a floating-point greater-than. func (c *Context) MkFPGT(lhs, rhs *Expr) *Expr { return newExpr(c, C.Z3_mk_fpa_gt(c.ptr, lhs.ptr, rhs.ptr)) } // MkFPLE creates a floating-point less-than-or-equal. func (c *Context) MkFPLE(lhs, rhs *Expr) *Expr { return newExpr(c, C.Z3_mk_fpa_leq(c.ptr, lhs.ptr, rhs.ptr)) } // MkFPGE creates a floating-point greater-than-or-equal. func (c *Context) MkFPGE(lhs, rhs *Expr) *Expr { return newExpr(c, C.Z3_mk_fpa_geq(c.ptr, lhs.ptr, rhs.ptr)) } // MkFPEq creates a floating-point equality. func (c *Context) MkFPEq(lhs, rhs *Expr) *Expr { return newExpr(c, C.Z3_mk_fpa_eq(c.ptr, lhs.ptr, rhs.ptr)) } // MkFPIsNaN creates a predicate checking if a floating-point number is NaN. func (c *Context) MkFPIsNaN(expr *Expr) *Expr { return newExpr(c, C.Z3_mk_fpa_is_nan(c.ptr, expr.ptr)) } // MkFPIsInf creates a predicate checking if a floating-point number is infinite. func (c *Context) MkFPIsInf(expr *Expr) *Expr { return newExpr(c, C.Z3_mk_fpa_is_infinite(c.ptr, expr.ptr)) } // MkFPIsZero creates a predicate checking if a floating-point number is zero. func (c *Context) MkFPIsZero(expr *Expr) *Expr { return newExpr(c, C.Z3_mk_fpa_is_zero(c.ptr, expr.ptr)) }